DE4443350C1 - Control and monitoring circuit for automobile electrical loads - Google Patents

Abstract

The circuit has each of the electrical loads (L1, L2) coupled to the voltage supply via a controlled load switch (S1, S2), with a sequence control (AS), for operation of the load switches in the correct sequence and supplied with a voltage signal (U1, U2) obtained from each load. The voltage signals allow the loads to be monitored in pairs, with the voltage monitoring terminals of both loads coupled together via a coupling network (VN). One of the loads is switched in and the other load is switched out, with the voltage at the voltage terminal of the latter load fed to an A/D converter (ADW, ADW').

Description

The invention relates to a circuit arrangement for Control and monitoring of electrical loads in one Motor vehicle with electrical loads that are controllable Load switches can be connected to a voltage, and one Sequence control device that the controllable Controlled load switch and that of any load Taps voltage signal.

Such circuit arrangements for monitoring electrical Loads usually have a measuring resistor with the electrical load is connected in series, with the Monitoring the load of the voltage drop across the Measuring resistance is evaluated.

The disadvantage here is that especially with very low-resistance electrical loads the measuring resistor must also be implemented with very low impedance in order to Do not impair the function of the electrical load.

Such low-impedance measuring resistors are only on complex to manufacture and have relatively large Dimensions. Another disadvantage is that the evaluation of very low voltages on low impedance Measuring resistances drop, a considerable amount of circuitry is required. These evaluation circuits are also especially against electromagnetic interference sensitive.

A circuit arrangement is therefore to be created, for the test there is no series resistance in the load circuit is needed.

A generic circuit arrangement that has no series resistances in the load circuits is known from DE 42 42 177 A1. At this circuit arrangement are via a controllable switch, all loads switched off during the duration of the test.  

DE 35 33 523 C2 is a circuit arrangement known with no series resistance between Load switch and load is provided. The Circuit arrangement has one for load monitoring Comparator on the voltage drop across electrical Load switches compared with a reference voltage.

The disadvantage here is that a review of the Load circuit is only open or short-circuited. Quantitative properties of the loads, especially their Resistance values cannot with this arrangement be monitored. A disadvantage of this circuit arrangement is further that because of the one used Comparators the loads are essentially the same must have electrical properties.

It is therefore the object of the invention to be simple and to create inexpensive circuitry without a series resistance in the load circuit is sufficient and still monitoring quantitative properties of the load, and while avoiding the disadvantages mentioned above, enables.

This object is achieved in that the Voltage signals are monitored at exactly two loads or that several loads are monitored in pairs that the voltage-monitored connections of both loads over one Link network are electrically connected and that one of the for monitoring the voltage signals Loads is switched on and the other load is switched off and that at the connection point between the link network and the other load applied voltage each an analog-digital converter is fed.

The circuit arrangement according to the invention is in many ways Respectful. So be used to monitor the loads  no costly large-scale low-impedance Resistors needed, but there will only be one at least an interconnection network containing a resistor intended.

Because the at least one resistor of the link network the full load current cannot flow through it relatively high resistance compared to the load resistors be carried out (test resistance approximately 10 times larger than the associated load resistance).

Since in the case of similar loads, the link network consists of no more than a resistance to Monitoring of both loads is used Circuit arrangement particularly simple and inexpensive.

It is also advantageous that the circuitry for Monitoring the loads is very low, so be For example, no test switches are required to control the loads to connect to a test facility, but the Monitoring of loads is done during normal Operation on a currently switched off or for testing temporarily switched off load.

It is also advantageous because the monitoring of the loads by the sequence control device is made with a quantitative monitoring of the Load resistance is possible.

Further advantageous refinements and developments emerge from the subclaims.

So it is advantageous for certain applications if that Link network for different current directions has different equivalent resistances. Hereby  the loads to be monitored can be very different Have load resistances.

It is also particularly advantageous that the microcomputer is off the two monitored voltage signals the internal resistances who can calculate loads. As a result, in addition to the usual test for short circuit or interruption of the Load cycle also a long-term change of Load resistances are determined.

A particularly advantageous application of this Circuit arrangement according to the invention is in the Monitoring glow plugs or glow plugs and Solenoid valves leading to the internal combustion engine Motor vehicle belong.

In the following an embodiment of the Circuit arrangement according to the invention with reference to the drawing shown and explained in more detail.

Show it

Fig. 1 is a block diagram of the circuit arrangement according to the invention;

Fig. 2 two examples of the formation of the link network.

Fig. 1 shows a circuit arrangement in which two loads (L1, L2) each via an electromechanical (relay) or electronic (e.g. power FET) load switch (S1, S2) to the operating voltage (UB) or alternatively can be switched to ground (GND).

The load switches (S1, S2) are replaced by the Sequence control device (AS) controlled, the Sequence control device for executing Control tasks a microcomputer (MC) has.  

At the connection points of load switches (S1, S2) and Loads (L1, L2) each have a voltage (U1, U2) tapped and the sequence control device (AS) fed. The sequence control device (AS) performs the Voltage signals (U1, U2) via one each Analog-digital converter (ADW, ADW ′) the microcomputer (MC) to.

Alternatively (not shown in FIG. 1) it can also be provided that the sequence control device (AS) has only one analog-to-digital converter and the voltage signal (U1, U2) to be tested alternately from the microcomputer (MC) to the inputs of the Analog-digital converter can be switched.

Furthermore, the circuit arrangement has a logic network (VN), which essentially represents a resistance network or, in the simplest case, consists of a single resistor (two advantageous embodiments of the logic network to be explained in greater detail are shown in FIG. 2) and that with the switched connections of both loads connected is.

To explain the mode of operation of the circuit arrangement, it is initially assumed that the loads (L1, L2) to be switched have roughly similar electrical properties, that is to say in particular similar internal resistances (RL1, RL2), and the connection network by means of a simple resistor (see FIG. 2A) is formed with the constant equivalent resistance value (RVN).

The loads (L1, L2) can, for example, glow plugs in be a self-igniting motor vehicle engine, such Glow plugs, for example, have an internal resistance of about 0.6 ohms.  

It is therefore hardly possible to have one in the load circuit Connect the test resistor in series with the load because this either affects the function of the load or the test resistor has a very low resistance would have to be, making the test resistor a large one Would have construction volume. Such test resistors are also expensive and difficult to manufacture as special products handle.

The procedure for determining the internal resistances (RL1, RL2) of the loads (L1, L2) is therefore as follows:
Suppose the load (L1) is switched on via the load switch (S1); the load switch (S2) is open. Then a current flows through the load (L2) via the switch (S1) and the link network (VN). At the connection point between the connection network (VN) and the load (L2), the sequence control device (AS) taps off the voltage (U2), which depends on the resistance ratio of the load (RL2) and the equivalent resistance of the connection network (RVN).

The equivalent resistor (RVN) advantageously needs the Linking network (VN) not to be smaller than that Load resistance (RL2); yes it should even be a multiple of Load resistance (RL2), since the load (L2) is only too Test purposes energized, but should not be turned on.

In a comparable way (load switch (S2) closed, (S1) open) the voltage value (U1) on the load (L1) be determined. Are both at the time of the test Loads (L1, L2) switched on, the load to be tested becomes (L1) for the (very short) duration of the test process switched off, whereby the function of the tested load in general is not affected.

From the voltage values (U1, U2) determined in this way, the Microcomputer (MC) using the known values for  the equivalent resistance (RVN) of the interconnection network (VN) the internal resistances (RL1, RL2) of the loads (L1, L2) to calculate. For example, (RL2) is calculated using the Relationship: RL2 = U2 × RVN / (U1-U2).

In addition to monitoring power interruptions and Short circuits in the load circuits is one of them quantitative check of load resistances possible.

It is particularly advantageous that even loads with a total different electrical properties due to the Circuit arrangement can be checked.

A glow plug, for example, is to be used as an example and a solenoid valve in an automobile engine as loads to be controlled and monitored (L1, L2) be provided. The glow plug has about 0.6 ohms a significantly lower internal resistance than that Solenoid valve (approx. 40 ohms).

So that the link network (VN) for both loads (L1, L2) a test resistor of the correct size trains, the link network (VN) can be trained that its equivalent resistance (RVN) is dependent on the current direction.

Such a configuration of the link network (VN) is shown in FIG. 2B. In the reverse direction of the diode (D), the equivalent resistance (RVN) of the connection network (VN) is equal to the value of the resistor (R1); in the forward direction of the diode (D) the equivalent resistance (RVN) of the interconnection network (VN) (neglecting the internal resistance of the diode) corresponds to that of the resistors R1 and R2 connected in parallel.

An adaptation of the link network is thus necessary Loads with different electrical properties easily possible.

Reference list

ADW, ADW ′ analog-to-digital converter
AS sequence control device
D diode
L1, L2 (electrical) loads
MC microcomputer
R1, R2 resistors
RL1, RL2 internal resistances of the loads (L1, L2)
RVN equivalent resistance of the interconnection network (VN)
S1, S2 load switch
VN link network
U1, U2 voltage signals or voltage values
UB operating voltage
GND mass

Claims (8)

1. Circuit arrangement for the control and monitoring of electrical loads in a motor vehicle with electrical loads (L1, L2) which can be connected to a voltage via controllable load switches (S1, S2), and a sequence control device (AS) which controls the controllable load switches (S1, S2) and which taps a voltage signal (U1, U2) from each load (L1, L2), characterized in that the voltage signals (U1, U2) are monitored at exactly two loads or that several loads are monitored in pairs, that the Voltage-monitored connections of both loads (L1, L2) are electrically connected to one another via a link network (VN) and that one of the loads (L1 or L2) is switched on to monitor the voltage signals (U2 or U1) and the other load (L2 or . L1) is switched off and that the voltage (U2, U1) present at the connection point between the linking network (VN) and the respective other load (L2 or L1) is one m analog-digital converter (ADW, ADW ') is supplied. 2. Circuit arrangement according to claim I, characterized characterized that only an analog-to-digital converter is provided and the sequence control when activated a load switch (S1, S2) the voltage signal (U2, U1) of the load that is not switched on (L2, L1) switches the analog-digital converter. 3. Circuit arrangement according to claim I or 2, characterized characterized in that the or the analog-digital converter (ADW, ADW ′) an integral part of the Sequence control device is.   4. Circuit arrangement according to claim I, characterized characterized in that the link network (VN) there is at least one resistor (R1). 5. Circuit arrangement according to claim 4, characterized characterized in that the link network (VN) additionally has at least one semiconductor diode (D) and the equivalent resistance (RVN) of the Linking network (VN) is dependent on the current direction. 6. Circuit arrangement according to claim I, characterized characterized in that the sequence control device (AS) has a microcomputer (MC) which consists of the the digital converter (s) (ADW, ADW ′) digitized voltage signals and the Equivalent resistance (RVN) of the interconnection network (VN) the internal resistances (RL1, RL2) of the loads (L1, L2) calculated. 7. Circuit arrangement according to claim 6, characterized characterized in that the resistance values of the Load resistances (L1, L2) are at least one Distinguish magnitude. 8. Circuit arrangement according to claim 7, characterized characterized in that the loads (L1, L2) as glow plugs and solenoid valves in the internal combustion engine Motor vehicle are executed.